The present disclosure is drawn to, among other things, a magnetoresistive device and a magnetoresistive memory comprising a plurality of such magnetoresistive devices. In some aspects, a magnetoresistive device may include a magnetically fixed region, a magnetically free region above or below the magnetically fixed region, and an intermediate region positioned between the magnetically fixed region and the magnetically free region, wherein the intermediate region includes a first dielectric material. The magnetoresistive device may also include encapsulation layers formed on opposing side walls of the magnetically free region, wherein the encapsulation layers include the first dielectric material.

The present disclosure is drawn to, among other things, a magnetoresistive device and a magnetoresistive memory comprising a plurality of such magnetoresistive devices. In some aspects, a magnetoresistive device may include a magnetically fixed region, a magnetically free region above or below the magnetically fixed region, and an intermediate region positioned between the magnetically fixed region and the magnetically free region, wherein the intermediate region includes a first dielectric material. The magnetoresistive device may also include encapsulation layers formed on opposing side walls of the magnetically free region, wherein the encapsulation layers include the first dielectric material.

A non-volatile data retention circuit includes a complementary latch configured to generate and store complementary non-volatile spin states corresponding to an input signal when in a write mode, and to concurrently generate a first charge current signal and a second charge current corresponding to the complementary non-volatile spin states when in read mode, and a differential amplifier coupled to the complementary latch and configured to generate an output signal based on the first and second charge current signals.

A non-volatile data retention circuit includes a complementary latch configured to generate and store complementary non-volatile spin states corresponding to an input signal when in a write mode, and to concurrently generate a first charge current signal and a second charge current corresponding to the complementary non-volatile spin states when in read mode, and a differential amplifier coupled to the complementary latch and configured to generate an output signal based on the first and second charge current signals.

A current sensor IC includes a unitary lead frame having a primary conductor with a first thickness and a secondary lead having a second thickness less than the first thickness. A semiconductor die adjacent to the primary conductor includes a magnetic field sensing circuit to sense a magnetic field associated with the current and generate a secondary signal indicative of the current. An insulation structure is disposed between the primary conductor and the die. A mold material encloses a first portion of the secondary lead and a second portion of the secondary lead that is exposed outside of the package has the second thickness. A method of manufacturing a current sensor IC includes providing a unitary lead frame sheet having a first thickness, decreasing a thickness of a portion of the sheet to provide a first portion with the first thickness and a second portion with a smaller thickness, and stamping the sheet to form a repeating lead frame pattern, with each pattern including a primary conductor formed from the first portion and secondary leads formed from the second portion.

Disclosed herein is a Hall sensor including a Hall element having a first principal surface, and a first magnetic body arranged on a side of the first principal surface, in which the first magnetic body has a first surface facing the first principal surface, and an area of a projection surface of the first magnetic body when viewed in plan from an opposite side of the Hall element is larger than an area of the first surface.

Disclosed herein is a Hall sensor including a Hall element having a first principal surface, and a first magnetic body arranged on a side of the first principal surface, in which the first magnetic body has a first surface facing the first principal surface, and an area of a projection surface of the first magnetic body when viewed in plan from an opposite side of the Hall element is larger than an area of the first surface.

A magnetic field sensor may include a semiconductor structure having a planar surface, and first, second, and third sensing devices. The semiconductor structure may include a semiconductor member having a two-dimensional electron gas therein, and an insulator member disposed on the semiconductor member. The first sensing device may be configured to sense magnetic field along a first axis parallel to the planar surface. The second sensing device may be configured to sense magnetic field along a second axis parallel to the planar surface, and orthogonal to the first axis. The third sensing device may be configured to sense a magnetic field along a third axis normal to the planar surface. Each of the first, second, and third sensing devices may be formed in the semiconductor structure and may include electrodes that extend from the insulator member to the two-dimensional electron gas.

A memory device is provided. The memory device includes a substrate, a spin-orbit torque layer and a magnetic tunneling junction (MTJ). The MTJ stacks with the spin-orbit torque layer over the substrate and includes a synthetic free layer, a barrier layer and a reference layer. The synthetic free layer includes a synthetic antiferromagnetic structure, a first spacer layer and a free layer, wherein the synthetic antiferromagnetic structure is disposed between the spin-orbit torque layer and the free layer. The barrier layer is disposed beside the synthetic free layer. The reference layer is disposed beside the barrier layer.

A memory device is provided. The memory device includes a substrate, a spin-orbit torque layer and a magnetic tunneling junction (MTJ). The MTJ stacks with the spin-orbit torque layer over the substrate and includes a synthetic free layer, a barrier layer and a reference layer. The synthetic free layer includes a synthetic antiferromagnetic structure, a first spacer layer and a free layer, wherein the synthetic antiferromagnetic structure is disposed between the spin-orbit torque layer and the free layer. The barrier layer is disposed beside the synthetic free layer. The reference layer is disposed beside the barrier layer.